Mechanisms of antigen processing and presentation

Dendritic cells in glomerulonephritis

Renal biopsies (n = 45) from patients with various forms of glomerulonephritis (GN), comprising mesangial IgA-GN (n = 25), focal glomerular sclerosis (n = 13) and acute GN (n = 7), were examined by double staining immunocytochemistry (APAAP, streptavidin-peroxidase) using unconjugated monoclonal antibodies (Ab) against--(i) the CD1b antigen expressed on dendritic cells (DCs), (ii) the invariant chain (Ii), and (iii) biotin-conjugated Ab against HLA-DR. In normal control kidneys (n = 7) without interstitial inflammation, CD1b-positive DCs were not detected. Glomerular endothelial cells and a few cells in mesangial areas showed double staining with the Ab against HLA-DR in Ii. In GN without active interstitial inflammation (n = 9), CD1b-positive DCs were not found. In biopsies with interstitial inflammation (n = 36) CD1b-positive DCs were found interspersed among other inflammatory cells. In seven of the biopsies showing IgA-GN DCs were seen in the vicinity of those glomeruli that exhibited either crescents or glomerular sclerosis with splitting of Bowman's capsule. In proximal tubular epithelial cells de novo expression of HLA-DR/Ii-chain was only seen when DCs were present. We conclude that in different forms of GN: (i) CD1b-positive DCs play an important role in the development of interstitial inflammation, and (ii) their presence may be related to the de novo coexpression of HLA-DR/Ii in tubular epithelial cells, possibly mediated through the production of interferon gamma and other cytokines.

Splenic B cells and antigen-specific B cells process anti-Ig in a similar manner

B lymphocytes can process and present antigen to T cells. However, the fate of native antigen after its binding to specific B cells, i.e., the intracellular events involved in the processing and recycling of the antigenic fragments to the cell surface for antigen presentation, are not well understood. In the present study, we demonstrate that murine B cells degrade anti-Ig molecules bound to their surface and release acid soluble fragments into the supernatant. We also demonstrate that the kinetics of this process are identical for anti-mu, anti-delta, and anti-light chain antibodies, indicating that both surface IgM and surface IgD are equally effective in binding antigen and directing its processing. We also describe the effects of azide, chloroquine, and irradiation on this process. To extend these studies to the processing of specifically bound antigen, we demonstrate that highly purified trinitrophenyl antigen-binding cells degrade anti-Ig molecules with the same kinetics as unpurified splenic B cells. Thus, this purified population provides a suitable model system for the analysis of antigen degradation by antigen-specific cells.

Bacterial antigen immunolabeling in macrophages after phagocytosis and degradation of Bacillus subtilis

After phagocytosis of Bacillus subtilis 168 by bone marrow-derived macrophages, the intracellular pathway followed by different antigens was studied by immunofluorescence and immunoelectron microscopy. Three different rabbit antisera were used: (i) an antiserum to B. subtilis whole cells mainly recognizing the cell wall constituents, (ii) an antiserum to teichoic acid, and (iii) an antiserum to peptidoglycan recognizing the disaccharide tetrapeptide molecules resulting from peptidoglycan degradation. During the first 3 h after phagocytosis of B. subtilis, the three antisera were confined to the same vacuolar compartments, as follows. They were first found in phagosomes gathered in the perinuclear region. Upon bacterial degradation, the three antisera colocalized in an increasing number of small dense vesicles, located in the perinuclear region, that seemed to result from the fragmentation of phagolysosomes. These vesicles correspond to an acidic compartment since they also stained for 3-(2,4-dinitroanilino)-3'-amino-N-methyldipropylamine, a drug known to accumulate in the acidic compartments of cells. At later time points, the antigens recognized by the three antisera followed different pathways. After 18 h, teichoic acid and peptidoglycan were no longer detectable in macrophages whereas an antigen(s) labeled with antiserum to B. subtilis whole cells remained stocked for several days in small acidic vesicles randomly distributed throughout the macrophage. This compartment appeared to be different from the one labeled during the first 3 h after ingestion of bacteria. These results suggest that the transport rate and the compartments implicated in antigen processing differ according to the antigen.